Zenpei Shimatani

INTRODUCTION To combat invading pathogens, cells develop an adaptive immune response by changing their own genetic information. In vertebrates, the generation of genetic variation (somatic hypermutation) is an essential process for diversification and affinity maturation of antibodies that function to detect and sequester various foreign biomolecules. The activation-induced cytidine deaminase (AID) carries out hypermutation by modifying deoxycytidine bases in the variable region of the immunoglobulin locus that produces antibody. AID-generated deoxyuridine in DNA is mutagenic as it can be miss-recognized as deoxythymine, resulting in C to T mutations. CRISPR (clustered regularly interspaced short palindromic repeats)/Cas (CRISPR-associated) is a prokaryotic adaptive immune system that records and degrades invasive foreign DNA or RNA. The CRISPR/Cas system cleaves and incorporates foreign DNA/RNA segments into the genomic region called the CRISPR array. The CRISPR array is transcribed to produce crispr-RNA that serves as guide RNA (gRNA) for recognition of the complementary foreign DNA/RNA in a ribonucleoprotein complex with Cas proteins, which degrade the target. The CRISPR/Cas system has been repurposed as a powerful genome editing tool, because it can be programmed to cleave specific DNA sequence by providing custom gRNAs. RATIONALE Although the precise mechanism by which AID specifically mutates the immunoglobulin locus remains elusive, targeting of AID activity is facilitated by the formation of a single-stranded DNA region, such as a transcriptional RNA/DNA hybrid (R-loop). The CRISPR/Cas system can be engineered to be nuclease-inactive. The nuclease-inactive form is capable of unfolding the DNA double strand in a protospacer adjacent motif (PAM) sequence-dependent manner so that the gRNA binds to complementary target DNA strand and forms an R-loop. The nuclease-deficient CRISPR/Cas system may serve as a suitable DNA-targeting module for AID to catalyze site-specific mutagenesis. RESULTS To determine whether AID activity can be specifically targeted by the CRISPR/Cas system, we combined dCas9 (a nuclease-deficient mutant of Cas9) from Streptococcus pyogenes and an AID ortholog, PmCDA1 from sea lamprey, to form a synthetic complex (Target-AID) by either engineering a fusion between the two proteins or attaching a SH3 (Src 3 homology) domain to the C terminus of dCas9 and a SHL (SH3 interaction ligand) to the C terminus of PmCDA1. Both of these complexes performed highly efficient site-directed mutagenesis. The mutational spectrum was analyzed in yeast and demonstrated that point mutations were dominantly induced at cytosines within the range of three to five bases surrounding the –18 position upstream of the PAM sequence on the noncomplementary strand to gRNA. The toxicity associated with the nuclease-based CRISPR/Cas9 system was greatly reduced in the Target-AID complexes. Combination of PmCDA1 with the nickase Cas9(D10A) mutant, which retains cleavage activity for noncomplementary single-stranded DNA, was more efficient in yeast but also induced deletions as well as point mutations in mammalian cells. Addition of the uracil DNA glycosylase inhibitor protein, which blocks the initial step of the uracil base excision repair pathway, suppressed collateral deletions and further improved targeting efficiency. Potential off-target effects were assessed by whole-genome sequencing of yeast as well as deep sequencing of mammalian cells for regions that contain mismatched target sequences. These results showed that off-target effects were comparable to those of conventional CRISPR/Cas systems, with a reduced risk of indel formation. CONCLUSION By expanding the genome editing potential of the CRISPR/Cas9 system by deaminase-mediated hypermutation, Target-AID demonstrated a very narrow range of targeted nucleotide substitution without the use of template DNA. Nickase Cas9 and uracil DNA glycosylase inhibitor protein can be used to boost the targeting efficiency. The reduced cytotoxicity will be beneficial for use in cells that are sensitive to artificial nucleases. Use of other types of nucleotide-modifying enzymes and/or other CRISPR-related systems with different PAM requirements will expand our genome-editing repertoire and capacity. A crippled CRISPR/Cas targets AID. In vertebrate adaptive immunity, cytosine deaminase (AID or PmCDA1) induces somatic hypermutation at single-stranded DNA regions formed during transcription. The bacterial CRISPR/Cas9 immunity system recognizes and cleaves invasive DNA in a gRNA-dependent manner. AID and nuclease-deficient CRISPR/Cas9 are engineered to form a hybrid complex (Target-AID) that performs programmable cytosine mutations in a range of a few bases surrounding the –18 position upstream of PAM sequence of the noncomplementary DNA strand.

Two evolutionarily distant plant species, rice (Oryza sativa L.), a short-day (SD) plant, and Arabidopsis thaliana, a long-day plant, share a conserved genetic network controlling photoperiodic flowering. The orthologous floral regulators-rice Heading date 1 (Hd1) and Arabidopsis CONSTANS (CO)-integrate circadian clock and external light signals into mRNA expression of the FLOWERING LOCUS T (FT) group floral inducer. Here, we report that the rice Early heading date 1 (Ehd1) gene, which confers SD promotion of flowering in the absence of a functional allele of Hd1, encodes a B-type response regulator that might not have an ortholog in the Arabidopsis genome. Ehd1 mRNA was induced by 1-wk SD treatment, and Ehd1 may promote flowering by inducing FT-like gene expression only under SD conditions. Microarray analysis further revealed a few MADS box genes downstream of Ehd1. Our results indicate that a novel two-component signaling cascade is integrated into the conserved pathway in the photoperiodic control of flowering in rice.

Brassinosteroids (BRs) are involved in many developmental processes and regulate many subsets of downstream genes throughout the plant kingdom. However, little is known about the BR signal transduction and response network in monocots. To identify novel BR-related genes in rice (Oryza sativa), we monitored the transcriptomic response of the brassinosteroid deficient1 (brd1) mutant, with a defective BR biosynthetic gene, to brassinolide treatment. Here, we describe a novel BR-induced rice gene BRASSINOSTEROID UPREGULATED1 (BU1), encoding a helix-loop-helix protein. Rice plants overexpressing BU1 (BU1:OX) showed enhanced bending of the lamina joint, increased grain size, and resistance to brassinazole, an inhibitor of BR biosynthesis. In contrast to BU1:OX, RNAi plants designed to repress both BU1 and its homologs displayed erect leaves. In addition, compared to the wild type, the induction of BU1 by exogenous brassinolide did not require de novo protein synthesis and it was weaker in a BR receptor mutant OsbriI (Oryza sativa brassinosteroid insensitive1, d61) and a rice G protein alpha subunit (RGA1) mutant d1. These results indicate that BU1 protein is a positive regulator of BR response: it controls bending of the lamina joint in rice and it is a novel primary response gene that participates in two BR signaling pathways through OsBRI1 and RGA1. Furthermore, expression analyses showed that BU1 is expressed in several organs including lamina joint, phloem, and epithelial cells in embryos. These results indicate that BU1 may participate in some other unknown processes modulated by BR in rice.

Recent methylome analyses of the entire Arabidopsis thaliana genome using various mutants have provided detailed information about the DNA methylation pattern and its function. However, information about DNA methylation in other plants is limited, partly because of the lack of mutants. To study DNA methylation in rice (Oryza sativa) we applied homologous recombination-mediated gene targeting to generate targeted disruptants of OsDRM2, a rice orthologue of DOMAINS REARRANGED METHYLASE 1 and 2 (DRM1/2), which encode DNA methyltransferases responsible for de novo and non-CG methylation in Arabidopsis. Whereas Arabidopsis drm1 drm2 double mutants showed no morphological alterations, targeted disruptants of rice OsDRM2 displayed pleiotropic developmental phenotypes in both vegetative and reproductive stages, including growth defects, semi-dwarfed stature, reductions in tiller number, delayed heading or no heading, abnormal panicle and spikelet morphology, and complete sterility. In these osdrm2 disruptants, a 13.9% decrease in 5-methylcytosine was observed by HPLC analysis. The CG and non-CG methylation levels were reduced in RIRE7/CRR1 retrotransposons, and in 5S rDNA repeats. Associated transcriptional activation was detected in RIRE7/CRR1. Furthermore, de novo methylation by an RNA-directed DNA methylation (RdDM) process involving transgene-derived exogenous small interfering RNA (siRNA) was deficient in osdrm2-disrupted cells. Impaired growth and abnormal DNA methylation of osdrm2 disruptants were restored by the complementation of wild-type OsDRM2 cDNA. Our results suggest that OsDRM2 is responsible for de novo, CG and non-CG methylation in rice genomic sequences, and that DNA methylation regulated by OsDRM2 is essential for proper rice development in both vegetative and reproductive stages.